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@INPROCEEDINGS{pivtoraiko_kelly_socs11,
author = {Mihail Pivtoraiko and Alonzo Kelly},
title = {Graduated Fidelity Motion Planning},
booktitle = {Proceedings of the International Symposium on Combinatorial Search},
year = {2011},
abstract = { This paper presents an approach to differentially
constrained robot motion planning and efficient
replanning. Satisfaction of differential constraints
is guaranteed by the search space which consists of
motions that satisfy the constraints by
construction. Any systematic replanning algorithm,
e.g. D*, can be utilized to search the state lattice
to find a motion plan that satisfies the
differential constraints, and to repair it
efficiently in the event of a change in the
environment. Further efficiency is obtained by
varying the fidelity of representation of the
planning problem. High fidelity is utilized where it
matters most, while it is lowered in the areas that
do not affect the quality of the plan
significantly. The paper presents a method of
modifying the fidelity between replans, thereby
enabling dynamic flexibility of the search space,
while maintaining its compatibility with replanning
algorithms. The approach is especially suited for
mobile robotics applications in unknown challenging
environments. We successfully applied the motion
planner on a real robot: the planner featured 10Hz
replan rate on minimal computing hardware [2], while
satisfying the car-like differential constraints. },
bib2html_pubtype = {Refereed Conference Papers},
bib2html_rescat = {Kinodynamic Planning}
}